pybind11/tests/test_factory_constructors.cpp

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Allow binding factory functions as constructors This allows you to use: cls.def(py::init(&factory_function)); where `factory_function` returns a pointer, holder, or value of the class type (or a derived type). Various compile-time checks (static_asserts) are performed to ensure the function is valid, and various run-time type checks where necessary. Some other details of this feature: - The `py::init` name doesn't conflict with the templated no-argument `py::init<...>()`, but keeps the naming consistent: the existing templated, no-argument one wraps constructors, the no-template, function-argument one wraps factory functions. - If returning a CppClass (whether by value or pointer) when an CppAlias is required (i.e. python-side inheritance and a declared alias), a dynamic_cast to the alias is attempted (for the pointer version); if it fails, or if returned by value, an Alias(Class &&) constructor is invoked. If this constructor doesn't exist, a runtime error occurs. - for holder returns when an alias is required, we try a dynamic_cast of the wrapped pointer to the alias to see if it is already an alias instance; if it isn't, we raise an error. - `py::init(class_factory, alias_factory)` is also available that takes two factories: the first is called when an alias is not needed, the second when it is. - Reimplement factory instance clearing. The previous implementation failed under python-side multiple inheritance: *each* inherited type's factory init would clear the instance instead of only setting its own type value. The new implementation here clears just the relevant value pointer. - dealloc is updated to explicitly set the leftover value pointer to nullptr and the `holder_constructed` flag to false so that it can be used to clear preallocated value without needing to rebuild the instance internals data. - Added various tests to test out new allocation/deallocation code. - With preallocation now done lazily, init factory holders can completely avoid the extra overhead of needing an extra allocation/deallocation. - Updated documentation to make factory constructors the default advanced constructor style. - If an `__init__` is called a second time, we have two choices: we can throw away the first instance, replacing it with the second; or we can ignore the second call. The latter is slightly easier, so do that.
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/*
tests/test_factory_constructors.cpp -- tests construction from a factory function
via py::init_factory()
Copyright (c) 2017 Jason Rhinelander <jason@imaginary.ca>
All rights reserved. Use of this source code is governed by a
BSD-style license that can be found in the LICENSE file.
*/
#include "pybind11_tests.h"
#include "constructor_stats.h"
#include <cmath>
// Classes for testing python construction via C++ factory function:
// Not publicly constructible, copyable, or movable:
Allow binding factory functions as constructors This allows you to use: cls.def(py::init(&factory_function)); where `factory_function` returns a pointer, holder, or value of the class type (or a derived type). Various compile-time checks (static_asserts) are performed to ensure the function is valid, and various run-time type checks where necessary. Some other details of this feature: - The `py::init` name doesn't conflict with the templated no-argument `py::init<...>()`, but keeps the naming consistent: the existing templated, no-argument one wraps constructors, the no-template, function-argument one wraps factory functions. - If returning a CppClass (whether by value or pointer) when an CppAlias is required (i.e. python-side inheritance and a declared alias), a dynamic_cast to the alias is attempted (for the pointer version); if it fails, or if returned by value, an Alias(Class &&) constructor is invoked. If this constructor doesn't exist, a runtime error occurs. - for holder returns when an alias is required, we try a dynamic_cast of the wrapped pointer to the alias to see if it is already an alias instance; if it isn't, we raise an error. - `py::init(class_factory, alias_factory)` is also available that takes two factories: the first is called when an alias is not needed, the second when it is. - Reimplement factory instance clearing. The previous implementation failed under python-side multiple inheritance: *each* inherited type's factory init would clear the instance instead of only setting its own type value. The new implementation here clears just the relevant value pointer. - dealloc is updated to explicitly set the leftover value pointer to nullptr and the `holder_constructed` flag to false so that it can be used to clear preallocated value without needing to rebuild the instance internals data. - Added various tests to test out new allocation/deallocation code. - With preallocation now done lazily, init factory holders can completely avoid the extra overhead of needing an extra allocation/deallocation. - Updated documentation to make factory constructors the default advanced constructor style. - If an `__init__` is called a second time, we have two choices: we can throw away the first instance, replacing it with the second; or we can ignore the second call. The latter is slightly easier, so do that.
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class TestFactory1 {
friend class TestFactoryHelper;
TestFactory1() : value("(empty)") { print_default_created(this); }
TestFactory1(int v) : value(std::to_string(v)) { print_created(this, value); }
TestFactory1(std::string v) : value(std::move(v)) { print_created(this, value); }
TestFactory1(TestFactory1 &&) = delete;
TestFactory1(const TestFactory1 &) = delete;
TestFactory1 &operator=(TestFactory1 &&) = delete;
TestFactory1 &operator=(const TestFactory1 &) = delete;
public:
std::string value;
~TestFactory1() { print_destroyed(this); }
};
// Non-public construction, but moveable:
class TestFactory2 {
friend class TestFactoryHelper;
TestFactory2() : value("(empty2)") { print_default_created(this); }
TestFactory2(int v) : value(std::to_string(v)) { print_created(this, value); }
TestFactory2(std::string v) : value(std::move(v)) { print_created(this, value); }
public:
TestFactory2(TestFactory2 &&m) { value = std::move(m.value); print_move_created(this); }
TestFactory2 &operator=(TestFactory2 &&m) { value = std::move(m.value); print_move_assigned(this); return *this; }
std::string value;
~TestFactory2() { print_destroyed(this); }
};
// Mixed direct/factory construction:
class TestFactory3 {
protected:
friend class TestFactoryHelper;
TestFactory3() : value("(empty3)") { print_default_created(this); }
TestFactory3(int v) : value(std::to_string(v)) { print_created(this, value); }
public:
TestFactory3(std::string v) : value(std::move(v)) { print_created(this, value); }
TestFactory3(TestFactory3 &&m) { value = std::move(m.value); print_move_created(this); }
TestFactory3 &operator=(TestFactory3 &&m) { value = std::move(m.value); print_move_assigned(this); return *this; }
std::string value;
virtual ~TestFactory3() { print_destroyed(this); }
};
// Inheritance test
class TestFactory4 : public TestFactory3 {
public:
TestFactory4() : TestFactory3() { print_default_created(this); }
TestFactory4(int v) : TestFactory3(v) { print_created(this, v); }
virtual ~TestFactory4() { print_destroyed(this); }
};
// Another class for an invalid downcast test
class TestFactory5 : public TestFactory3 {
public:
TestFactory5(int i) : TestFactory3(i) { print_created(this, i); }
virtual ~TestFactory5() { print_destroyed(this); }
};
class TestFactory6 {
protected:
int value;
bool alias = false;
public:
TestFactory6(int i) : value{i} { print_created(this, i); }
TestFactory6(TestFactory6 &&f) { print_move_created(this); value = f.value; alias = f.alias; }
TestFactory6(const TestFactory6 &f) { print_copy_created(this); value = f.value; alias = f.alias; }
virtual ~TestFactory6() { print_destroyed(this); }
virtual int get() { return value; }
bool has_alias() { return alias; }
};
class PyTF6 : public TestFactory6 {
public:
// Special constructor that allows the factory to construct a PyTF6 from a TestFactory6 only
// when an alias is needed:
PyTF6(TestFactory6 &&base) : TestFactory6(std::move(base)) { alias = true; print_created(this, "move", value); }
PyTF6(int i) : TestFactory6(i) { alias = true; print_created(this, i); }
PyTF6(PyTF6 &&f) : TestFactory6(std::move(f)) { print_move_created(this); }
PyTF6(const PyTF6 &f) : TestFactory6(f) { print_copy_created(this); }
PyTF6(std::string s) : TestFactory6((int) s.size()) { alias = true; print_created(this, s); }
virtual ~PyTF6() { print_destroyed(this); }
int get() override { PYBIND11_OVERLOAD(int, TestFactory6, get, /*no args*/); }
};
class TestFactory7 {
protected:
int value;
bool alias = false;
public:
TestFactory7(int i) : value{i} { print_created(this, i); }
TestFactory7(TestFactory7 &&f) { print_move_created(this); value = f.value; alias = f.alias; }
TestFactory7(const TestFactory7 &f) { print_copy_created(this); value = f.value; alias = f.alias; }
virtual ~TestFactory7() { print_destroyed(this); }
virtual int get() { return value; }
bool has_alias() { return alias; }
};
class PyTF7 : public TestFactory7 {
public:
PyTF7(int i) : TestFactory7(i) { alias = true; print_created(this, i); }
PyTF7(PyTF7 &&f) : TestFactory7(std::move(f)) { print_move_created(this); }
PyTF7(const PyTF7 &f) : TestFactory7(f) { print_copy_created(this); }
virtual ~PyTF7() { print_destroyed(this); }
int get() override { PYBIND11_OVERLOAD(int, TestFactory7, get, /*no args*/); }
};
class TestFactoryHelper {
public:
// Non-movable, non-copyable type:
// Return via pointer:
static TestFactory1 *construct1() { return new TestFactory1(); }
// Holder:
static std::unique_ptr<TestFactory1> construct1(int a) { return std::unique_ptr<TestFactory1>(new TestFactory1(a)); }
// pointer again
static TestFactory1 *construct1_string(std::string a) { return new TestFactory1(a); }
// Moveable type:
// pointer:
static TestFactory2 *construct2() { return new TestFactory2(); }
// holder:
static std::unique_ptr<TestFactory2> construct2(int a) { return std::unique_ptr<TestFactory2>(new TestFactory2(a)); }
// by value moving:
static TestFactory2 construct2(std::string a) { return TestFactory2(a); }
// shared_ptr holder type:
// pointer:
static TestFactory3 *construct3() { return new TestFactory3(); }
// holder:
static std::shared_ptr<TestFactory3> construct3(int a) { return std::shared_ptr<TestFactory3>(new TestFactory3(a)); }
};
TEST_SUBMODULE(factory_constructors, m) {
// Define various trivial types to allow simpler overload resolution:
py::module m_tag = m.def_submodule("tag");
#define MAKE_TAG_TYPE(Name) \
struct Name##_tag {}; \
py::class_<Name##_tag>(m_tag, #Name "_tag").def(py::init<>()); \
m_tag.attr(#Name) = py::cast(Name##_tag{})
MAKE_TAG_TYPE(pointer);
MAKE_TAG_TYPE(unique_ptr);
MAKE_TAG_TYPE(move);
MAKE_TAG_TYPE(shared_ptr);
MAKE_TAG_TYPE(derived);
MAKE_TAG_TYPE(TF4);
MAKE_TAG_TYPE(TF5);
MAKE_TAG_TYPE(null_ptr);
MAKE_TAG_TYPE(base);
MAKE_TAG_TYPE(invalid_base);
MAKE_TAG_TYPE(alias);
MAKE_TAG_TYPE(unaliasable);
MAKE_TAG_TYPE(mixed);
// test_init_factory_basic, test_bad_type
py::class_<TestFactory1>(m, "TestFactory1")
.def(py::init([](unique_ptr_tag, int v) { return TestFactoryHelper::construct1(v); }))
.def(py::init(&TestFactoryHelper::construct1_string)) // raw function pointer
.def(py::init([](pointer_tag) { return TestFactoryHelper::construct1(); }))
.def(py::init([](py::handle, int v, py::handle) { return TestFactoryHelper::construct1(v); }))
.def_readwrite("value", &TestFactory1::value)
;
py::class_<TestFactory2>(m, "TestFactory2")
.def(py::init([](pointer_tag, int v) { return TestFactoryHelper::construct2(v); }))
.def(py::init([](unique_ptr_tag, std::string v) { return TestFactoryHelper::construct2(v); }))
.def(py::init([](move_tag) { return TestFactoryHelper::construct2(); }))
.def_readwrite("value", &TestFactory2::value)
;
// Stateful & reused:
int c = 1;
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auto c4a = [c](pointer_tag, TF4_tag, int a) { (void) c; return new TestFactory4(a);};
Allow binding factory functions as constructors This allows you to use: cls.def(py::init(&factory_function)); where `factory_function` returns a pointer, holder, or value of the class type (or a derived type). Various compile-time checks (static_asserts) are performed to ensure the function is valid, and various run-time type checks where necessary. Some other details of this feature: - The `py::init` name doesn't conflict with the templated no-argument `py::init<...>()`, but keeps the naming consistent: the existing templated, no-argument one wraps constructors, the no-template, function-argument one wraps factory functions. - If returning a CppClass (whether by value or pointer) when an CppAlias is required (i.e. python-side inheritance and a declared alias), a dynamic_cast to the alias is attempted (for the pointer version); if it fails, or if returned by value, an Alias(Class &&) constructor is invoked. If this constructor doesn't exist, a runtime error occurs. - for holder returns when an alias is required, we try a dynamic_cast of the wrapped pointer to the alias to see if it is already an alias instance; if it isn't, we raise an error. - `py::init(class_factory, alias_factory)` is also available that takes two factories: the first is called when an alias is not needed, the second when it is. - Reimplement factory instance clearing. The previous implementation failed under python-side multiple inheritance: *each* inherited type's factory init would clear the instance instead of only setting its own type value. The new implementation here clears just the relevant value pointer. - dealloc is updated to explicitly set the leftover value pointer to nullptr and the `holder_constructed` flag to false so that it can be used to clear preallocated value without needing to rebuild the instance internals data. - Added various tests to test out new allocation/deallocation code. - With preallocation now done lazily, init factory holders can completely avoid the extra overhead of needing an extra allocation/deallocation. - Updated documentation to make factory constructors the default advanced constructor style. - If an `__init__` is called a second time, we have two choices: we can throw away the first instance, replacing it with the second; or we can ignore the second call. The latter is slightly easier, so do that.
2017-06-13 01:52:48 +00:00
// test_init_factory_basic, test_init_factory_casting
py::class_<TestFactory3, std::shared_ptr<TestFactory3>>(m, "TestFactory3")
.def(py::init([](pointer_tag, int v) { return TestFactoryHelper::construct3(v); }))
.def(py::init([](shared_ptr_tag) { return TestFactoryHelper::construct3(); }))
.def("__init__", [](TestFactory3 &self, std::string v) { new (&self) TestFactory3(v); }) // placement-new ctor
// factories returning a derived type:
.def(py::init(c4a)) // derived ptr
.def(py::init([](pointer_tag, TF5_tag, int a) { return new TestFactory5(a); }))
// derived shared ptr:
.def(py::init([](shared_ptr_tag, TF4_tag, int a) { return std::make_shared<TestFactory4>(a); }))
.def(py::init([](shared_ptr_tag, TF5_tag, int a) { return std::make_shared<TestFactory5>(a); }))
// Returns nullptr:
.def(py::init([](null_ptr_tag) { return (TestFactory3 *) nullptr; }))
.def_readwrite("value", &TestFactory3::value)
;
// test_init_factory_casting
py::class_<TestFactory4, TestFactory3, std::shared_ptr<TestFactory4>>(m, "TestFactory4")
.def(py::init(c4a)) // pointer
;
// Doesn't need to be registered, but registering makes getting ConstructorStats easier:
py::class_<TestFactory5, TestFactory3, std::shared_ptr<TestFactory5>>(m, "TestFactory5");
// test_init_factory_alias
// Alias testing
py::class_<TestFactory6, PyTF6>(m, "TestFactory6")
.def(py::init([](base_tag, int i) { return TestFactory6(i); }))
.def(py::init([](alias_tag, int i) { return PyTF6(i); }))
.def(py::init([](alias_tag, std::string s) { return PyTF6(s); }))
.def(py::init([](alias_tag, pointer_tag, int i) { return new PyTF6(i); }))
.def(py::init([](base_tag, pointer_tag, int i) { return new TestFactory6(i); }))
.def(py::init([](base_tag, alias_tag, pointer_tag, int i) { return (TestFactory6 *) new PyTF6(i); }))
.def("get", &TestFactory6::get)
.def("has_alias", &TestFactory6::has_alias)
.def_static("get_cstats", &ConstructorStats::get<TestFactory6>, py::return_value_policy::reference)
.def_static("get_alias_cstats", &ConstructorStats::get<PyTF6>, py::return_value_policy::reference)
;
// test_init_factory_dual
// Separate alias constructor testing
py::class_<TestFactory7, PyTF7, std::shared_ptr<TestFactory7>>(m, "TestFactory7")
.def(py::init(
[](int i) { return TestFactory7(i); },
[](int i) { return PyTF7(i); }))
.def(py::init(
[](pointer_tag, int i) { return new TestFactory7(i); },
[](pointer_tag, int i) { return new PyTF7(i); }))
.def(py::init(
[](mixed_tag, int i) { return new TestFactory7(i); },
[](mixed_tag, int i) { return PyTF7(i); }))
.def(py::init(
[](mixed_tag, std::string s) { return TestFactory7((int) s.size()); },
[](mixed_tag, std::string s) { return new PyTF7((int) s.size()); }))
.def(py::init(
[](base_tag, pointer_tag, int i) { return new TestFactory7(i); },
[](base_tag, pointer_tag, int i) { return (TestFactory7 *) new PyTF7(i); }))
.def(py::init(
[](alias_tag, pointer_tag, int i) { return new PyTF7(i); },
[](alias_tag, pointer_tag, int i) { return new PyTF7(10*i); }))
.def(py::init(
[](shared_ptr_tag, base_tag, int i) { return std::make_shared<TestFactory7>(i); },
[](shared_ptr_tag, base_tag, int i) { auto *p = new PyTF7(i); return std::shared_ptr<TestFactory7>(p); }))
.def(py::init(
[](shared_ptr_tag, invalid_base_tag, int i) { return std::make_shared<TestFactory7>(i); },
[](shared_ptr_tag, invalid_base_tag, int i) { return std::make_shared<TestFactory7>(i); })) // <-- invalid alias factory
.def("get", &TestFactory7::get)
.def("has_alias", &TestFactory7::has_alias)
.def_static("get_cstats", &ConstructorStats::get<TestFactory7>, py::return_value_policy::reference)
.def_static("get_alias_cstats", &ConstructorStats::get<PyTF7>, py::return_value_policy::reference)
;
// test_placement_new_alternative
// Class with a custom new operator but *without* a placement new operator (issue #948)
class NoPlacementNew {
public:
NoPlacementNew(int i) : i(i) { }
static void *operator new(std::size_t s) {
auto *p = ::operator new(s);
py::print("operator new called, returning", reinterpret_cast<uintptr_t>(p));
return p;
}
static void operator delete(void *p) {
py::print("operator delete called on", reinterpret_cast<uintptr_t>(p));
::operator delete(p);
}
int i;
};
// As of 2.2, `py::init<args>` no longer requires placement new
Allow binding factory functions as constructors This allows you to use: cls.def(py::init(&factory_function)); where `factory_function` returns a pointer, holder, or value of the class type (or a derived type). Various compile-time checks (static_asserts) are performed to ensure the function is valid, and various run-time type checks where necessary. Some other details of this feature: - The `py::init` name doesn't conflict with the templated no-argument `py::init<...>()`, but keeps the naming consistent: the existing templated, no-argument one wraps constructors, the no-template, function-argument one wraps factory functions. - If returning a CppClass (whether by value or pointer) when an CppAlias is required (i.e. python-side inheritance and a declared alias), a dynamic_cast to the alias is attempted (for the pointer version); if it fails, or if returned by value, an Alias(Class &&) constructor is invoked. If this constructor doesn't exist, a runtime error occurs. - for holder returns when an alias is required, we try a dynamic_cast of the wrapped pointer to the alias to see if it is already an alias instance; if it isn't, we raise an error. - `py::init(class_factory, alias_factory)` is also available that takes two factories: the first is called when an alias is not needed, the second when it is. - Reimplement factory instance clearing. The previous implementation failed under python-side multiple inheritance: *each* inherited type's factory init would clear the instance instead of only setting its own type value. The new implementation here clears just the relevant value pointer. - dealloc is updated to explicitly set the leftover value pointer to nullptr and the `holder_constructed` flag to false so that it can be used to clear preallocated value without needing to rebuild the instance internals data. - Added various tests to test out new allocation/deallocation code. - With preallocation now done lazily, init factory holders can completely avoid the extra overhead of needing an extra allocation/deallocation. - Updated documentation to make factory constructors the default advanced constructor style. - If an `__init__` is called a second time, we have two choices: we can throw away the first instance, replacing it with the second; or we can ignore the second call. The latter is slightly easier, so do that.
2017-06-13 01:52:48 +00:00
py::class_<NoPlacementNew>(m, "NoPlacementNew")
.def(py::init<int>())
Allow binding factory functions as constructors This allows you to use: cls.def(py::init(&factory_function)); where `factory_function` returns a pointer, holder, or value of the class type (or a derived type). Various compile-time checks (static_asserts) are performed to ensure the function is valid, and various run-time type checks where necessary. Some other details of this feature: - The `py::init` name doesn't conflict with the templated no-argument `py::init<...>()`, but keeps the naming consistent: the existing templated, no-argument one wraps constructors, the no-template, function-argument one wraps factory functions. - If returning a CppClass (whether by value or pointer) when an CppAlias is required (i.e. python-side inheritance and a declared alias), a dynamic_cast to the alias is attempted (for the pointer version); if it fails, or if returned by value, an Alias(Class &&) constructor is invoked. If this constructor doesn't exist, a runtime error occurs. - for holder returns when an alias is required, we try a dynamic_cast of the wrapped pointer to the alias to see if it is already an alias instance; if it isn't, we raise an error. - `py::init(class_factory, alias_factory)` is also available that takes two factories: the first is called when an alias is not needed, the second when it is. - Reimplement factory instance clearing. The previous implementation failed under python-side multiple inheritance: *each* inherited type's factory init would clear the instance instead of only setting its own type value. The new implementation here clears just the relevant value pointer. - dealloc is updated to explicitly set the leftover value pointer to nullptr and the `holder_constructed` flag to false so that it can be used to clear preallocated value without needing to rebuild the instance internals data. - Added various tests to test out new allocation/deallocation code. - With preallocation now done lazily, init factory holders can completely avoid the extra overhead of needing an extra allocation/deallocation. - Updated documentation to make factory constructors the default advanced constructor style. - If an `__init__` is called a second time, we have two choices: we can throw away the first instance, replacing it with the second; or we can ignore the second call. The latter is slightly easier, so do that.
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.def(py::init([]() { return new NoPlacementNew(100); }))
.def_readwrite("i", &NoPlacementNew::i)
;
// test_reallocations
// Class that has verbose operator_new/operator_delete calls
struct NoisyAlloc {
NoisyAlloc(const NoisyAlloc &) = default;
Allow binding factory functions as constructors This allows you to use: cls.def(py::init(&factory_function)); where `factory_function` returns a pointer, holder, or value of the class type (or a derived type). Various compile-time checks (static_asserts) are performed to ensure the function is valid, and various run-time type checks where necessary. Some other details of this feature: - The `py::init` name doesn't conflict with the templated no-argument `py::init<...>()`, but keeps the naming consistent: the existing templated, no-argument one wraps constructors, the no-template, function-argument one wraps factory functions. - If returning a CppClass (whether by value or pointer) when an CppAlias is required (i.e. python-side inheritance and a declared alias), a dynamic_cast to the alias is attempted (for the pointer version); if it fails, or if returned by value, an Alias(Class &&) constructor is invoked. If this constructor doesn't exist, a runtime error occurs. - for holder returns when an alias is required, we try a dynamic_cast of the wrapped pointer to the alias to see if it is already an alias instance; if it isn't, we raise an error. - `py::init(class_factory, alias_factory)` is also available that takes two factories: the first is called when an alias is not needed, the second when it is. - Reimplement factory instance clearing. The previous implementation failed under python-side multiple inheritance: *each* inherited type's factory init would clear the instance instead of only setting its own type value. The new implementation here clears just the relevant value pointer. - dealloc is updated to explicitly set the leftover value pointer to nullptr and the `holder_constructed` flag to false so that it can be used to clear preallocated value without needing to rebuild the instance internals data. - Added various tests to test out new allocation/deallocation code. - With preallocation now done lazily, init factory holders can completely avoid the extra overhead of needing an extra allocation/deallocation. - Updated documentation to make factory constructors the default advanced constructor style. - If an `__init__` is called a second time, we have two choices: we can throw away the first instance, replacing it with the second; or we can ignore the second call. The latter is slightly easier, so do that.
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NoisyAlloc(int i) { py::print(py::str("NoisyAlloc(int {})").format(i)); }
NoisyAlloc(double d) { py::print(py::str("NoisyAlloc(double {})").format(d)); }
~NoisyAlloc() { py::print("~NoisyAlloc()"); }
static void *operator new(size_t s) { py::print("noisy new"); return ::operator new(s); }
static void *operator new(size_t, void *p) { py::print("noisy placement new"); return p; }
static void operator delete(void *p, size_t) { py::print("noisy delete"); ::operator delete(p); }
static void operator delete(void *, void *) { py::print("noisy placement delete"); }
#if defined(_MSC_VER) && _MSC_VER < 1910
// MSVC 2015 bug: the above "noisy delete" isn't invoked (fixed in MSVC 2017)
static void operator delete(void *p) { py::print("noisy delete"); ::operator delete(p); }
#endif
};
py::class_<NoisyAlloc>(m, "NoisyAlloc")
// Since these overloads have the same number of arguments, the dispatcher will try each of
// them until the arguments convert. Thus we can get a pre-allocation here when passing a
// single non-integer:
.def("__init__", [](NoisyAlloc *a, int i) { new (a) NoisyAlloc(i); }) // Regular constructor, runs first, requires preallocation
.def(py::init([](double d) { return new NoisyAlloc(d); }))
// The two-argument version: first the factory pointer overload.
.def(py::init([](int i, int) { return new NoisyAlloc(i); }))
// Return-by-value:
.def(py::init([](double d, int) { return NoisyAlloc(d); }))
// Old-style placement new init; requires preallocation
.def("__init__", [](NoisyAlloc &a, double d, double) { new (&a) NoisyAlloc(d); })
// Requires deallocation of previous overload preallocated value:
.def(py::init([](int i, double) { return new NoisyAlloc(i); }))
// Regular again: requires yet another preallocation
.def("__init__", [](NoisyAlloc &a, int i, std::string) { new (&a) NoisyAlloc(i); })
;
// static_assert testing (the following def's should all fail with appropriate compilation errors):
#if 0
struct BadF1Base {};
struct BadF1 : BadF1Base {};
struct PyBadF1 : BadF1 {};
py::class_<BadF1, PyBadF1, std::shared_ptr<BadF1>> bf1(m, "BadF1");
// wrapped factory function must return a compatible pointer, holder, or value
bf1.def(py::init([]() { return 3; }));
// incompatible factory function pointer return type
bf1.def(py::init([]() { static int three = 3; return &three; }));
// incompatible factory function std::shared_ptr<T> return type: cannot convert shared_ptr<T> to holder
// (non-polymorphic base)
bf1.def(py::init([]() { return std::shared_ptr<BadF1Base>(new BadF1()); }));
#endif
}